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Chapter 1: Introduction

Chapter 1: Introduction. Outline. Embedded systems overview What are they? Design challenge – optimizing design metrics Technologies Processor technologies IC technologies Design technologies. Embedded systems overview. Computing systems are everywhere

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Chapter 1: Introduction

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  1. Chapter 1: Introduction

  2. Outline • Embedded systems overview • What are they? • Design challenge – optimizing design metrics • Technologies • Processor technologies • IC technologies • Design technologies

  3. Embedded systems overview • Computing systems are everywhere • Most of us think of “desktop” computers • PC’s • Laptops • Mainframes • Servers • But there’s another type of computing system • Far more common...

  4. Embedded systems overview • Embedded computing systems • Computing systems embedded within electronic devices • Hard to define. Nearly any computing system other than a desktop computer • Billions of units produced yearly, versus millions of desktop units • Perhaps 50 per household and per automobile Computers are in here... and here... and even here... Lots more of these, though they cost a lot less each.

  5. A “short list” of embedded systems And the list goes on and on Anti-lock brakes Auto-focus cameras Automatic teller machines Automatic toll systems Automatic transmission Avionic systems Battery chargers Camcorders Cell phones Cell-phone base stations Cordless phones Cruise control Curbside check-in systems Digital cameras Disk drives Electronic card readers Electronic instruments Electronic toys/games Factory control Fax machines Fingerprint identifiers Home security systems Life-support systems Medical testing systems Modems MPEG decoders Network cards Network switches/routers On-board navigation Pagers Photocopiers Point-of-sale systems Portable video games Printers Satellite phones Scanners Smart ovens/dishwashers Speech recognizers Stereo systems Teleconferencing systems Televisions Temperature controllers Theft tracking systems TV set-top boxes VCR’s, DVD players Video game consoles Video phones Washers and dryers

  6. Some common characteristics of embedded systems • Single-functioned • Executes a single program, repeatedly • Tightly-constrained • Low cost, low power, small, fast, etc. • Reactive and real-time • Continually reacts to changes in the system’s environment • Must compute certain results in real-time without delay

  7. Digital camera chip CCD CCD preprocessor Pixel coprocessor D2A A2D lens JPEG codec Microcontroller Multiplier/Accum DMA controller Display ctrl Memory controller ISA bus interface UART LCD ctrl An embedded system example -- a digital camera • Single-functioned -- always a digital camera • Tightly-constrained -- Low cost, low power, small, fast • Reactive and real-time -- only to a small extent

  8. Design challenge – optimizing design metrics • Obvious design goal: • Construct an implementation with desired functionality • Key design challenge: • Simultaneously optimize numerous design metrics • Design metric • A measurable feature of a system’s implementation • Optimizing design metrics is a key challenge

  9. Design challenge – optimizing design metrics • Common metrics • Unit cost: the monetary cost of manufacturing each copy of the system, excluding NRE cost • NRE cost (Non-Recurring Engineering cost): The one-time monetary cost of designing the system • Size: the physical space required by the system • Performance: the execution time or throughput of the system • Power: the amount of power consumed by the system • Flexibility: the ability to change the functionality of the system without incurring heavy NRE cost

  10. Design challenge – optimizing design metrics • Common metrics (continued) • Time-to-prototype: the time needed to build a working version of the system • Time-to-market: the time required to develop a system to the point that it can be released and sold to customers • Maintainability: the ability to modify the system after its initial release • Correctness, safety, many more

  11. Expertise with both software and hardware is needed to optimize design metrics Not just a hardware or software expert, as is common A designer must be comfortable with various technologies in order to choose the best for a given application and constraints Power Digital camera chip CCD Performance Size CCD preprocessor Pixel coprocessor D2A A2D lens NRE cost JPEG codec Microcontroller Multiplier/Accum DMA controller Display ctrl Memory controller ISA bus interface UART LCD ctrl Design metric competition -- improving one may worsen others Hardware Software

  12. Time required to develop a product to the point it can be sold to customers Market window Period during which the product would have highest sales Average time-to-market constraint is about 8 months Delays can be costly Revenues ($) Time (months) Time-to-market: a demanding design metric

  13. Simplified revenue model Product life = 2W, peak at W Time of market entry defines a triangle, representing market penetration Triangle area equals revenue Loss The difference between the on-time and delayed triangle areas Peak revenue Peak revenue from delayed entry Revenues ($) On-time Market fall Market rise Delayed D W 2W On-time Delayed entry entry Time Losses due to delayed market entry

  14. Area = 1/2 * base * height On-time = 1/2 * 2W * W Delayed = 1/2 * (W-D+W)*(W-D) Percentage revenue loss = (D(3W-D)/2W2)*100% Try some examples Peak revenue Peak revenue from delayed entry Revenues ($) On-time Market fall Market rise Delayed D W 2W On-time Delayed entry entry Time Losses due to delayed market entry (cont.) • Lifetime 2W=52 wks, delay D=4 wks • (4*(3*26 –4)/2*26^2) = 22% • Lifetime 2W=52 wks, delay D=10 wks • (10*(3*26 –10)/2*26^2) = 50% • Delays are costly!

  15. Costs: Unit cost: the monetary cost of manufacturing each copy of the system, excluding NRE cost NRE cost (Non-Recurring Engineering cost): The one-time monetary cost of designing the system total cost = NRE cost + unit cost * # of units per-product cost = total cost / # of units = (NRE cost / # of units) + unit cost Amortizing NRE cost over the units results in an additional $200 per unit NRE and unit cost metrics • Example • NRE=$2000, unit=$100 • For 10 units • total cost = $2000 + 10*$100 = $3000 • per-product cost = $2000/10 + $100 = $300

  16. Compare technologies by costs -- best depends on quantity Technology A: NRE=$2,000, unit=$100 Technology B: NRE=$30,000, unit=$30 Technology C: NRE=$100,000, unit=$2 NRE and unit cost metrics • But, must also consider time-to-market

  17. The performance design metric • Widely-used measure of system, widely-abused • Clock frequency, instructions per second – not good measures • Digital camera example – a user cares about how fast it processes images, not clock speed or instructions per second • Latency (response time) • Time between task start and end • e.g., Camera’s A and B process images in 0.25 seconds • Throughput • Tasks per second, e.g. Camera A processes 4 images per second • Throughput can be more than latency seems to imply due to concurrency, e.g. Camera B may process 8 images per second (by capturing a new image while previous image is being stored). • Speedup of B over S = B’s performance / A’s performance • Throughput speedup = 8/4 = 2

  18. Three key embedded system technologies • Technology • A manner of accomplishing a task, especially using technical processes, methods, or knowledge • Three key technologies for embedded systems • Processor technology • IC technology • Design technology

  19. Processor technology • The architecture of the computation engine used to implement a system’s desired functionality • Processor does not have to be programmable • “Processor” not equal to general-purpose processor Controller Datapath Controller Datapath Controller Datapath Control logic index Control logic and State register Control logic and State register Registers Register file total Custom ALU State register + General ALU IR PC IR PC Data memory Data memory Program memory Data memory Program memory Assembly code for: total = 0 for i =1 to … Assembly code for: total = 0 for i =1 to … General-purpose(“software”) Application-specific Single-purpose(“hardware”)

  20. Processor technology • Processors vary in their customization for the problem at hand total = 0 for i = 1 to N loop total += M[i] end loop Desired functionality General-purpose processor Application-specific processor Single-purpose processor

  21. Controller Datapath Control logic and State register Register file General ALU IR PC Program memory Data memory Assembly code for: total = 0 for i =1 to … General-purpose processors • Programmable device used in a variety of applications • Also known as “microprocessor” • Features • Program memory • General datapath with large register file and general ALU • User benefits • Low time-to-market and NRE costs • High flexibility • “Pentium” the most well-known, but there are hundreds of others

  22. Datapath Controller Control logic index total State register + Data memory Single-purpose processors • Digital circuit designed to execute exactly one program • a.k.a. coprocessor, accelerator or peripheral • Features • Contains only the components needed to execute a single program • No program memory • Benefits • Fast • Low power • Small size

  23. Application-specific processors • Programmable processor optimized for a particular class of applications having common characteristics • Compromise between general-purpose and single-purpose processors • Features • Program memory • Optimized datapath • Special functional units • Benefits • Some flexibility, good performance, size and power Controller Datapath Control logic and State register Registers Custom ALU IR PC Data memory Program memory Assembly code for: total = 0 for i =1 to …

  24. gate oxide IC package IC source channel drain Silicon substrate IC technology • The manner in which a digital (gate-level) implementation is mapped onto an IC • IC: Integrated circuit, or “chip” • IC technologies differ in their customization to a design • IC’s consist of numerous layers (perhaps 10 or more) • IC technologies differ with respect to who builds each layer and when

  25. IC technology • Three types of IC technologies • Full-custom/VLSI • Semi-custom ASIC (gate array and standard cell) • PLD (Programmable Logic Device)

  26. Full-custom/VLSI • All layers are optimized for an embedded system’s particular digital implementation • Placing transistors • Sizing transistors • Routing wires • Benefits • Excellent performance, small size, low power • Drawbacks • High NRE cost (e.g., $300k), long time-to-market

  27. Semi-custom • Lower layers are fully or partially built • Designers are left with routing of wires and maybe placing some blocks • Benefits • Good performance, good size, less NRE cost than a full-custom implementation (perhaps $10k to $100k) • Drawbacks • Still require weeks to months to develop

  28. PLD (Programmable Logic Device) • All layers already exist • Designers can purchase an IC • Connections on the IC are either created or destroyed to implement desired functionality • Field-Programmable Gate Array (FPGA) very popular • Benefits • Low NRE costs, almost instant IC availability • Drawbacks • Bigger, expensive (perhaps $30 per unit), power hungry, slower

  29. 10,000 1,000 100 Logic transistors per chip (in millions) 10 1 0.1 0.01 0.001 1981 1983 1985 1987 1989 1991 1993 1995 1997 1999 2001 2003 2005 2007 2009 Moore’s law • The most important trend in embedded systems • Predicted in 1965 by Intel co-founder Gordon Moore IC transistor capacity has doubled roughly every 18 months for the past several decades Note: logarithmic scale

  30. Moore’s law • Wow • This growth rate is hard to imagine, most people underestimate • How many ancestors do you have from 20 generations ago • i.e., roughly how many people alive in the 1500’s did it take to make you? • 220 = more than 1 million people • (This underestimation is the key to pyramid schemes!)

  31. Graphical illustration of Moore’s law • Something that doubles frequently grows more quickly than most people realize! • A 2002 chip can hold about 15,000 1981 chips inside itself 1981 1984 1987 1990 1993 1996 1999 2002 10,000 transistors 150,000,000 transistors Leading edge chip in 1981 Leading edge chip in 2002

  32. Compilation/ Synthesis Libraries/ IP Test/ Verification System specification System synthesis Hw/Sw/ OS Model simulat./ checkers Compilation/Synthesis: Automates exploration and insertion of implementation details for lower level. Behavioral specification Behavior synthesis Cores Hw-Sw cosimulators Libraries/IP: Incorporates pre-designed implementation from lower abstraction level into higher level. RT specification RT synthesis RT components HDL simulators Test/Verification: Ensures correct functionality at each level, thus reducing costly iterations between levels. Logic specification Logic synthesis Gates/ Cells Gate simulators To final implementation Design Technology • The manner in which we convert our concept of desired system functionality into an implementation

  33. Design productivity exponential increase • Exponential increase over the past few decades 100,000 10,000 1,000 100 Productivity (K) Trans./Staff – Mo. 10 1 0.1 0.01 1981 2009 1995 2007 1997 1993 1989 1999 2001 1991 1983 2003 1987 1985 2005

  34. Sequential program code (e.g., C, VHDL) Behavioral synthesis (1990's) Compilers (1960's,1970's) Register transfers Assembly instructions RT synthesis (1980's, 1990's) Assemblers, linkers (1950's, 1960's) Logic equations / FSM's Logic synthesis (1970's, 1980's) Machine instructions Logic gates Implementation Microprocessor plus program bits: “software” VLSI, ASIC, or PLD implementation: “hardware” The co-design ladder • In the past: • Hardware and software design technologies were very different • Recent maturation of synthesis enables a unified view of hardware and software • Hardware/software “codesign” The choice of hardware versus software for a particular function is simply a tradeoff among various design metrics, like performance, power, size, NRE cost, and especially flexibility; there is no fundamental difference between what hardware or software can implement.

  35. General-purpose processor ASIP Single- purpose processor General, providing improved: Customized, providing improved: Flexibility Maintainability NRE cost Time- to-prototype Time-to-market Cost (low volume) Power efficiency Performance Size Cost (high volume) PLD Semi-custom Full-custom Independence of processor and IC technologies • Basic tradeoff • General vs. custom • With respect to processor technology or IC technology • The two technologies are independent

  36. 10,000 100,000 1,000 10,000 100 1000 Logic transistors per chip (in millions) Gap Productivity (K) Trans./Staff-Mo. 10 100 IC capacity 1 10 0.1 1 productivity 0.01 0.1 0.001 0.01 1981 1983 1985 1987 1989 1991 1993 1995 1997 1999 2001 2003 2005 2007 2009 Design productivity gap • While designer productivity has grown at an impressive rate over the past decades, the rate of improvement has not kept pace with chip capacity

  37. 10,000 100,000 1,000 10,000 100 1000 Logic transistors per chip (in millions) Gap Productivity (K) Trans./Staff-Mo. 10 100 IC capacity 1 10 0.1 1 productivity 0.01 0.1 0.001 0.01 1981 1983 1985 1987 1989 1991 1993 1995 1997 1999 2001 2003 2005 2007 2009 Design productivity gap • 1981 leading edge chip required 100 designer months • 10,000 transistors / 100 transistors/month • 2002 leading edge chip requires 30,000 designer months • 150,000,000 / 5000 transistors/month • Designer cost increase from $1M to $300M

  38. Team 15 60000 16 16 18 50000 19 40000 23 24 30000 Months until completion 20000 43 Individual 10000 0 10 20 30 40 Number of designers The mythical man-month • The situation is even worse than the productivity gap indicates • In theory, adding designers to team reduces project completion time • In reality, productivity per designer decreases due to complexities of team management and communication • In the software community, known as “the mythical man-month” (Brooks 1975) • At some point, can actually lengthen project completion time! (“Too many cooks”) • 1M transistors, 1 designer=5000 trans/month • Each additional designer reduces for 100 trans/month • So 2 designers produce 4900 trans/month each

  39. Summary • Embedded systems are everywhere • Key challenge: optimization of design metrics • Design metrics compete with one another • A unified view of hardware and software is necessary to improve productivity • Three key technologies • Processor: general-purpose, application-specific, single-purpose • IC: Full-custom, semi-custom, PLD • Design: Compilation/synthesis, libraries/IP, test/verification

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